needed to avoid creating preferential flow paths while piling which could allow contaminated
groundwater and leachates to be transported downwards. Hollow tubular steel piles can be
expensive for piling in contaminated ground when compared with other displacement piles,
but they are useful in overcoming obstructions which could cause problems when driving
precast concrete or boring displacement piles. Large displacement piles are unlikely to form
transfer conduits for contaminants, although untreated wooden piles may allow ‘wicking’of
volatile organics. End-bearing H-piles can form long-term flow conduits into aquifers
(particularly when a driving shoe is needed) and it may be necessary for the piles to be
hydraulically isolated from the contaminated zone.
The factor of durabilityaffects the choice of material for a pile. Although timber piles are
cheap in some countries they are liable to decay above groundwater level, and in marine
structures they suffer damage by destructive mollusc-type organisms. Precast concrete piles
do not suffer corrosion in saline water below the ‘splash zone’, and rich well-compacted
concrete can withstand attack from quite high concentrations of sulphates in soils and
groundwaters. Cast-in-place concrete piles are not so resistant to aggressive substances
because of difficulties in ensuring complete compaction of the concrete, but protection can
be provided against attack by placing the concrete in permanent linings of coated light-gauge
metal or plastics. Check lists for durability of man-made materials in the ground are
provided in Eurocode 2 (EC2) BSEN 1992-1: 2004 Design of Concrete Structures, Part 1-1:
General rules and BS8500 for concrete, and for steel in Eurocode 3 (EC3) BSEN 1993-1:
2005 Design of Steel Structures, Part 1-1: General rules and BSEN 1993 Part 5, Piling
(EC3–5).
Steel piles can have a long life in ordinary soil conditions, if they are completely embedded
in undisturbed soil, but the portions of a pile exposed to sea water or to disturbed soil must
be protected against corrosion by cathodic means, if a long life is required. Corrosion rates
can be derived from the corrosion tables published in EC3-5 Annex F. Recent work by Corus
Construction and Industrial(2.3, 2.4)has refined guidelines for corrosion allowances for steel
embedded in contaminated soil. ‘Mariner grade’steel to ASTM standard can give performance
improvement of 2 to 3 times that of conventional steels in marine splash zones.
Other factors influence the choice of one or another type of pile in each main classification,
and these are discussed in the following pages, in which the various types of pile are
described in detail. In UK practice specifications for pile materials, manufacturing
requirements (including dimensional tolerances), workmanship and contract documentation
are given in a publication of the Institution of Civil Engineers(2.5). This specification is
generally consistent with the requirements in EC7 and the associated standards for the
‘Execution of special geotechnical works’– BSEN 1536: 1999 Bored piles, BSEN 12063:
1999 Sheet piling, BS EN 12699: 2000 Displacement piles and BSEN 14199: 2005
Micropiles.
Having selected a certain type or types of pile as being suitable for the location and type
of structure for the ground conditions at the site and for the requirements of durability, the
final choice is then made on the basis of cost. However, the total cost of a piled foundation
is not simply the quoted price per metre run of piling or even the more accurate comparison
of cost per pile per kN of working load carried. The most important consideration is the
overall cost of the foundation work including the main contractor’s costs and overheads.
It has been noted in Chapter 1 that a piling contractor is unlikely to quote a fixed price
based on a predetermined length of pile. Extra payment will be sought if the piles are
required to depths greater than those predicted at the tendering stage. Thus a contractor’s
Types of pile 13